CN103464931B - A kind of high-toughness submerged arc welding sintered flux and preparation method - Google Patents
A kind of high-toughness submerged arc welding sintered flux and preparation method Download PDFInfo
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- CN103464931B CN103464931B CN201310353025.5A CN201310353025A CN103464931B CN 103464931 B CN103464931 B CN 103464931B CN 201310353025 A CN201310353025 A CN 201310353025A CN 103464931 B CN103464931 B CN 103464931B
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Abstract
A kind of high-toughness submerged arc welding sintered flux, comprise dry powder composition and binding agent, in dry powder composition, the percentage by weight of each component is: reheating magnesia: 20 ~ 30%, corundum: 20 ~ 30%, fluorite: 10 ~ 20%, wollastonite: 10 ~ 20%, lithia: 1 ~ 3%, rutile: 4 ~ 8%, ferrosilicon: 2 ~ 4%, ferrotianium: 1 ~ 3%, manganese metal: 1 ~ 3%, diboron trioxide: 1 ~ 5%, rare earth fluoride: 1 ~ 3%; Binding agent adopts KP1.Sintered flux welding technological properties of the present invention is excellent.Arc stability during welding, appearance of weld are attractive in appearance, weld seam infiltrates that angle is moderate, bottom slag is very easily removed in slab groove.Sintered flux of the present invention can with most of carbon steel welding wire with the use of, comprehensive mechanical performance is excellent, especially has higher low-temperature impact toughness.
Description
Technical field
The invention belongs to technical field of welding materials, particularly relate to a kind of high-toughness submerged arc welding sintered flux and preparation method.
Background technology
Submerged-arc welding can adopt fysed flux and sintered flux to coordinate corresponding welding wire to carry out structure welding, and wherein fysed flux is comparatively large owing to consuming energy, the defects such as iron loss is large, the scope of application constantly reduces, and sintered flux is little owing to having power consumption, the features such as iron loss is little, just constantly expand range of application.Meanwhile, along with enterprise is to production efficiency and Automation of Manufacturing Process, the raising of mechanization demand, submerged-arc welding becomes low-alloy high-strength steel construction and commonly uses one of welding method, and particularly in the welding process of the long weld seam of large slab, the advantage of submerged-arc welding is more obvious.Therefore the research of submerged-arc welding sintered flux is just seemed very urgent, at present, major part solder flux research emphasis is mainly placed on following two aspects: one, to the raising aspect of the mechanical properties of deposited metal or weld metal, as a kind of in (patent No.: CN102363252A) sintered flux of low alkalinity high tenacity; (patent No.: CN101314200) high-strength high-ductility fluorine alkalescent sintered flux, this solder flux combination property involved by two kinds of patents is good, but the first pull-up slag effect is also slightly inadequate in deep groove.Two, to the raising aspect of welding efficiency aspect, as (patent No.: CN1415454) one is used for multifibres, the sintered flux of high speed Lincoln weld, (patent No.: CN1699009) one is used for multifibres, the high toughness sintering solder of high speed Lincoln weld, this solder flux involved by two patents has higher welding efficiency and comprehensive mechanical performance, there is slab groove bottom too and take off the feature that slag effect shows slightly deficiency, the space that the low-temperature impact toughness of the deposited metal of solder flux that simultaneously above-mentioned four patents are mentioned also is improved, therefore for the problems referred to above, this patent proposes a kind of High Toughness SAW Agglomerated Flux with the removability of slag in excellent groove, this solder flux can mate the welding that most of carbon steel welding wire carries out low-alloy steel structure, there is excellent mechanical performance, there is deposited metal low-temperature impact toughness feature that the ground floor removability of slag in higher groove is excellent and higher especially, improve the anti-brittle failure ability of weld seam, reduce the working strength of operating personnel, high degree improves production efficiency, therefore, there are good market prospects.
Summary of the invention
The object of this invention is to provide a kind of High Toughness SAW Agglomerated Flux with the removability of slag in excellent groove, this solder flux can mate the welding that most of carbon steel welding wire carries out low-alloy steel structure, under acquisition meets the prerequisite of AWS and GB/T respective standard performance requirement, also there is the excellent groove bottom weld seam removability of slag and higher weld metal low-temperature impact toughness, reduce the working strength of operating personnel, increase work efficiency and the security of structure.
Another object of the present invention is to provide the preparation method of above-mentioned High Toughness SAW Agglomerated Flux.
To achieve these goals, the technical solution adopted in the present invention is: a kind of high-toughness submerged arc welding sintered flux, comprise dry powder composition and binding agent, in dry powder composition, the percentage by weight of each component is: reheating magnesia: 20 ~ 30%, corundum: 20 ~ 30%, fluorite: 10 ~ 20%, wollastonite: 10 ~ 20%, lithia: 1 ~ 3%, rutile: 4 ~ 8%, ferrosilicon: 2 ~ 4%, ferrotianium: 1 ~ 3%, manganese metal: 1 ~ 3%, diboron trioxide: 1 ~ 5%, rare earth fluoride: 1 ~ 3%; Binding agent adopts M=2.6, the KP1 of 40 ~ 43Be when 20 DEG C.
A kind of preparation method of high-toughness submerged arc welding sintered flux, be first reheating magnesia by percentage by weight: 20 ~ 30%, corundum: 20 ~ 30%, fluorite: 10 ~ 20%, wollastonite: 10 ~ 20%, lithia: 1 ~ 3%, rutile: 4 ~ 8%, ferrosilicon: 2 ~ 4%, ferrotianium: 1 ~ 3%, manganese metal: 1 ~ 3%, diboron trioxide: 1 ~ 5%, rare earth fluoride: after the dry powder of 1 ~ 3% mixes in proportion, add M=2.6 again, when 20 DEG C, the KP1 of 40 ~ 43Be is as binding agent granulation, again through 200 DEG C of low temperature drying 1h, 780 DEG C of high temperature sintering 40min, again through cooling, screening, packaging, prepared by solder flux.
The preparation method of high-toughness submerged arc welding sintered flux of the present invention, the flux particle of described screening is 20 ~ 60 orders.
Owing to have employed technique scheme, the present invention has following beneficial effect: in this sintered flux, the Main Function of each composition is summarized as follows:
Reheating magnesia: have slag making, regulates the basicity of slag, viscosity, mobility and improves the effect of appearance of weld.When fused magnesite content is more than 30%, the viscosity of slag reduces, slag fluidity is deteriorated, spreadability reduces, when reheating magnesia content lower than 20% time, slag fluidity is excessively good, causes appearance of weld to be deteriorated, cause slag basicity to decline simultaneously, during welding, reduce the low-temperature impact toughness of the ground floor removability of slag and deposited metal in groove.Thus fused magnesite content in solder flux is controlled 20 ~ 30%.
Fluorite: appropriate fluorite can reduce the surface tension of liquid metal, reduces the hydrogen content of deposited metal, improves the physical property of slag, reduces weld porosity sensitiveness.Fluorite content lower than 10% time, make slag fluidity excessively good, appearance of weld is bad, and in weld seam, hydrogen content is higher, and easily occurs pore.When fluorite content is more than 20%, arc stability is deteriorated, appearance of weld is deteriorated, and the content therefore controlling fluorite in solder flux is 10 ~ 20%.
Corundum: Main Function is slag making, forms alumino-silicate, regulates the fusing point of slag, viscosity.When corundum content lower than 20% time, fusing point and the viscosity of slag are lower, and the fragility of skull reduces, and spreadability is poor; When corundum content higher than 30% time, the basicity of slag declines, and the deoxidation of slag reduces, and have impact on the low-temperature impact toughness of deposited metal.Thus controlling corundum content in solder flux is 20 ~ 30%.
Wollastonite: be mainly used as slag making, forms silicate and improves slag fusing point and droplet transfer performance, also have desulphuration.When wollastonite content lower than 10% time, slag making amount is less, can not form enough silicate compounds, reduce the fragility of skull, droplet transfer particle is comparatively large, and ripple is thicker, when wollastonite content higher than 20% time, the siliconising of butt welded seam can be increased, affect the performance of weld seam.Thus should control wollastonite content in solder flux is 10 ~ 20%.
Rutile: main as refinement fusing point, improves appearance of weld and improves the removability of slag.When in solder flux, rutile content is less than 1%, ripple is comparatively thick, weld seam has part dry slag phenomenon, and when in solder flux, rutile content reaches 5%, slag comes off completely, but easily reduces slag basicity, reduces the combination property of weld seam.Therefore controlling rutile content in solder flux is 1 ~ 5%.
Manganese metal: add and mainly play deoxidation, the effect of desulfurization and adjustment viscosity coefficient of dross, and be transitioned in metal the intensity adjusting weld metal.Manganese addition lower than 1% time, deoxidation, desulfurized effect are not obvious, and when manganese addition reaches 3%, toughness Adjustment effect reaches best, and the content therefore controlling manganese metal in solder flux is 1 ~ 3%.
Ferrotianium and ferrosilicon: ferrotianium and ferrosilicon add the effect mainly playing deoxidation, ferrotianium, when ferrosilicon content is less than 1% and 2% respectively, weld seam deoxidation effect is not good, improve the oxidisability of slag, the de-slag effect of impact, ferrosilicon addition higher than 4% time, silicone content in weld seam can be increased, reduce weld seam combination property.It is best that ferrotianium reaches 3% deoxidation effect, but add cost, and thus control ferrosilicon and ferrotianium addition are respectively 2 ~ 4% and 1 ~ 3%.
Lithia and diboron trioxide: the Main Function of these two kinds of materials is the coefficients of expansion adjusting slag together with rutile, the bottom removability of slag in the groove improving slag.When lithia and diboron trioxide content are less than 1%; in groove, the removability of slag of ground floor weld seam slag is poor; when lithia and diboron trioxide reach 3% and 5% respectively; slag shrinks serious a little; affect the protected effect of slag, therefore in solder flux, the content of lithia and diboron trioxide all should control 1 ~ 5%.
Rare earth fluoride be mainly used as dehydrogenation, purification weld seam, when rare earth fluoride addition lower than 1% time, the catharsis of weld seam is not obvious, when rare earth fluoride addition higher than 3% time, clean-up effect also tends towards stability, and thus the addition of rare earth fluoride should control 1 ~ 3%.
In addition, sintered flux welding technological properties of the present invention is excellent.Arc stability during welding, appearance of weld are attractive in appearance, weld seam infiltrates that angle is moderate, bottom slag is very easily removed in slab groove.Sintered flux of the present invention can with most of carbon steel welding wire with the use of, comprehensive mechanical performance is excellent, especially has higher low-temperature impact toughness.
Detailed description of the invention
Below by way of the description of detailed description of the invention, the present invention will be further described, but this is limitation of the present invention not, and those skilled in the art, according to basic thought of the present invention, can make various modification or modification, only otherwise depart from basic thought of the present invention, all within the scope of the present invention.
Table 1 is the solder flux dry powder formulation percentage by weight proportioning table of embodiment 1 to embodiment 3.
Table 1 embodiment dry powder formulation percentage by weight proportioning
Be after the solder flux dry powder of table 1 embodiment 1 ~ embodiment 3 mixes in proportion by percentage by weight, add M=2.6 again, when 20 DEG C, the KP1 of 40 ~ 43Be is as binding agent granulation, again through 200 DEG C of low temperature drying 1h, 780 DEG C of high temperature sintering 40min, then with air cooling but, cross 20 ~ 60 mesh sieves, pack, make finished product solder flux.
Table 2 is welding wire and the deposited metal composition that embodiment 1 arrives embodiment 3.
Table 2 embodiment welding wire and deposited metal composition
In embodiment, the mechanical property of deposited metal is as shown in table 3.
Table 3 embodiment deposited metal mechanical property
The test removability of slag: according to removability of slag test requirements document in GB/T25776-2010 standard, in standard double V-groove, carries out the removability of slag in groove to above-described embodiment and a routine domestic main flow solder flux more as shown in table 4.
The comparison of the table 4 embodiment test removability of slag
Sample | Embodiment 1 | Embodiment 2 | Embodiment 3 | Certain main flow solder flux |
Bottom takes off slag rate (%) | 31 | 44 | 60 | 17 |
Bottom takes off slag rate D=(l
0-l)/l
0× 100%.L
0-welding bead total length (mm); The not de-slag total length (mm) of l-
Test technology: each Example formulations skull is more crisp, and hardness is moderate, appearance of weld is good, and has higher low temperature impact properties, coordinates the deposited metal performance of H09Mn2H welding wire to reach AWSA5.17, GB/T5293 and NB/T47018 standard-required.
Claims (3)
1. a high-toughness submerged arc welding sintered flux, comprise dry powder composition and binding agent, it is characterized in that: in dry powder composition, the percentage by weight of each component is: reheating magnesia: 20 ~ 30%, corundum: 20 ~ 30%, fluorite: 10 ~ 20%, wollastonite: 10 ~ 20%, lithia: 1 ~ 3%, rutile: 4 ~ 8%, ferrosilicon: 2 ~ 4%, ferrotianium: 1 ~ 3%, manganese metal: 1 ~ 3%, diboron trioxide: 1 ~ 5%, rare earth fluoride: 1 ~ 3%; Binding agent adopts M=2.6, the KP1 of 40 ~ 43Be when 20 DEG C.
2. the preparation method of a high-toughness submerged arc welding sintered flux as claimed in claim 1, it is characterized in that: be reheating magnesia by percentage by weight: 20 ~ 30%, corundum: 20 ~ 30%, fluorite: 10 ~ 20%, wollastonite: 10 ~ 20%, lithia: 1 ~ 3%, rutile: 4 ~ 8%, ferrosilicon: 2 ~ 4%, ferrotianium: 1 ~ 3%, manganese metal: 1 ~ 3%, diboron trioxide: 1 ~ 5%, rare earth fluoride: after the dry powder of 1 ~ 3% mixes in proportion, add M=2.6 again, when 20 DEG C, the KP1 of 40 ~ 43Be is as binding agent granulation, again through 200 DEG C of low temperature drying 1h, 780 DEG C of high temperature sintering 40min, again through cooling, screening, packaging, prepared by solder flux.
3. the preparation method of high-toughness submerged arc welding sintered flux as claimed in claim 2, is characterized in that: the flux particle of described screening is 20 ~ 60 orders.
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Families Citing this family (11)
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CN104400256A (en) * | 2014-10-31 | 2015-03-11 | 天津市宏远钛铁有限公司 | Low-hygroscopicity submerged-arc welding sintered flux and preparation method thereof |
CN104708230B (en) * | 2015-03-02 | 2016-10-12 | 武汉天高熔接股份有限公司 | High efficiency sintered flux and production technology thereof |
CN104708231B (en) * | 2015-03-17 | 2017-06-16 | 北京金威焊材有限公司 | Nickel-base strip pole electroslag welding sintered flux |
CN104816106B (en) * | 2015-05-22 | 2017-07-28 | 天津市永昌焊丝有限公司 | A kind of special submerged-arc horizontal solder flux of pressure-bearing storage tank |
CN106041371B (en) * | 2016-07-04 | 2018-10-19 | 常州大学 | A kind of smelting type welding flux used for submerged arc welding and its preparation method and application |
CN107322189A (en) * | 2017-07-14 | 2017-11-07 | 招商局重工(江苏)有限公司 | A kind of sintered flux for high heat-input submerged-arc welding |
CN109175788B (en) * | 2018-11-26 | 2021-01-26 | 北京金威焊材有限公司 | Submerged arc sintered flux for stainless steel at low temperature |
CN110238493B (en) * | 2019-06-25 | 2020-12-18 | 钢铁研究总院 | Submerged arc welding wire, submerged arc welding material and application thereof |
US11772206B2 (en) * | 2019-09-20 | 2023-10-03 | Lincoln Global, Inc. | High chromium creep resistant weld metal for arc welding of thin walled steel members |
US11772207B2 (en) * | 2019-09-20 | 2023-10-03 | Lincoln Global, Inc. | High chromium creep resistant weld metal for arc welding of thick walled steel members |
CN113210925A (en) * | 2021-05-10 | 2021-08-06 | 合肥紫金钢管股份有限公司 | Welding flux for submerged-arc welding of 12Cr2Mo1R alloy steel pipe and preparation method thereof |
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EP0176411A1 (en) * | 1984-09-11 | 1986-04-02 | La Soudure Autogene Francaise | Solid flux for submerged arc welding |
JPS6218277B2 (en) * | 1981-07-31 | 1987-04-22 | Kobe Steel Ltd | |
CN102416533A (en) * | 2011-04-27 | 2012-04-18 | 杜荣臻 | Sintered flux for filament swinging submerged arc surfacing of continuous casting roller and preparation method for sintered flux |
CN102909492A (en) * | 2012-10-17 | 2013-02-06 | 西安理工大学 | High-welding-speed sintered flux for submerged-arc welding of X100 pipeline steel and preparation method thereof |
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2013
- 2013-08-14 CN CN201310353025.5A patent/CN103464931B/en not_active Expired - Fee Related
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6218277B2 (en) * | 1981-07-31 | 1987-04-22 | Kobe Steel Ltd | |
EP0176411A1 (en) * | 1984-09-11 | 1986-04-02 | La Soudure Autogene Francaise | Solid flux for submerged arc welding |
CN102416533A (en) * | 2011-04-27 | 2012-04-18 | 杜荣臻 | Sintered flux for filament swinging submerged arc surfacing of continuous casting roller and preparation method for sintered flux |
CN102909492A (en) * | 2012-10-17 | 2013-02-06 | 西安理工大学 | High-welding-speed sintered flux for submerged-arc welding of X100 pipeline steel and preparation method thereof |
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